REALIZATION OF A VARIABLE RESOLUTION MODIFIED SEMIFLASH ADC BASED ON BIT SEGMENTATION SCHEME

A modified variable resolution semiflash ADC, based on ‘bit segmentation scheme’, is presented. Its speed and comparator count are identical to a normal flash ADC. An 8-bit ADC has 256 different bit combinations. Sixteen consecutive bit combinations from the MSB side – beginning with the first one, remain unaltered for such an ADC. It continues this way till the last group of sixteen bits. In the designed circuit, the four MSB and four LSB bits are determined in the first and second part of the clock. Following the same logic, the bits in a 16-bit ADC can be found out in only two clock cycles by employing only fifteen comparators. It implies that a higher resolution ADC can easily be determined with low power and small die area. It is tested in P-SIM Professional 9 for an 8-bit ADC and curves drawn to establish the validity of the proposal

Digital Background Self-Calibration Technique for Compensating Transition Offsets in Reference-less Flash ADCs

This Dissertation focusses on proving that background calibration using adaptive algorithms are low-cost, stable and effective methods for obtaining high accuracy in flash A/D converters. An integrated reference-less 3-bit flash ADC circuit has been successfully designed and taped out in UMC 180 nm CMOS technology in order to prove the efficiency of our proposed background calibration. References for ADC transitions have been virtually implemented built-in in the comparators dynamic-latch topology by a controlled mismatch added to each comparator input front-end. An external very simple DAC block (calibration bank) allows control the quantity of mismatch added in each comparator front-end and, therefore, compensate the offset of its effective transition with respect to the nominal value. In order to assist to the estimation of the offset of the prototype comparators, an auxiliary A/D converter with higher resolution and lower conversion speed than the flash ADC is used: a 6-bit capacitive-DAC SAR type. Special care in synchronization of analogue sampling instant in both ADCs has been taken into account. In this thesis, a criterion to identify the optimum parameters of the flash ADC design with adaptive background calibration has been set. With this criterion, the best choice for dynamic latch architecture, calibration bank resolution and flash ADC resolution are selected. The performance of the calibration algorithm have been tested, providing great programmability to the digital processor that implements the algorithm, allowing to choose the algorithm limits, accuracy and quantization errors in the arithmetic. Further, systematic controlled offset can be forced in the comparators of the flash ADC in order to have a more exhaustive test of calibration

High-speed Low-voltage CMOS Flash Analog-to-Digital Converter for Wideband Communication System-on-a-Chip

With higher-level integration driven by increasingly complex digital systems and downscaling CMOS processes available, system-on-a-chip (SoC) is an emerging technology of low power, high cost effectiveness and high reliability and is exceedingly attractive for applications in high-speed data conversion wireless and wideband communication systems. This research presents a novel ADC comparator design methodology; the speed and performance of which is not restricted by the supply voltage reduction and device linearity deterioration in scaling-down CMOS processes. By developing a dynamic offset suppression technique and a circuit optimization method, the comparator can achieve a 3 dB frequency of 2 GHz in 130 nanometer (nm) CMOS process. Combining this new comparator design and a proposed pipelined thermometer-Gray- binary encoder designed by the DCVSPG logic, a high-speed, low-voltage clocked-digital- comparator (CDC) pipelined CMOS flash ADC architecture is proposed for wideband communication SoC. This architecture has advantages of small silicon area, low power, and low cost. Three CDC-based pipelined CMOS flash ADCs were implemented in 130 nm CMOS process and their experimental results are reported: 1. 4-b, 2.5-GSPS ADC: SFDR of 21.48-dB, SNDR of 15.99-dB, ENOB of 2.4-b, ERBW of 1-GHz, power of 7.9-mW, and area of 0.022-mm2. 2. 4-b, 4-GSPS ADC: SFDR of 25-dB, SNDR of 18.6-dB, ENOB of 2.8-b, ERBW of 2-GHz, power of 11-mW. 3. 6-b, 4-GSPS ADC: SFDR of 48-dB at a signal frequency of 11.72-MHz, SNDR of 34.43-dB, ENOB of 5.4-b, power of 28-mW. An application of the proposed CDC-based pipelined CMOS flash ADC is 1-GHz bandwidth, 2.5-GSPS digital receiver on a chip. To verify the performance of the receiver, a mixed-signal block-level simulation and verification flow was built in Cadence AMS integrated platform. The verification results of the digital receiver using a 4-b 2.5-GSPS CDC-based pipelined CMOS ADC, a 256-point, 12-point kernel function FFT and a frequency detection logic show that two tone signals up to 1125 MHz can be detected and discriminated. A notable contribution of this research is that the proposed ADC architecture and the comparator design with dynamic offset suppression and optimization are extremely suitable for future VDSM CMOS processes and make all-digital receiver SoC design practical

Noise shaping Asynchronous SAR ADC based time to digital converter

Time-to-digital converters (TDCs) are key elements for the digitization of timing information in modern mixed-signal circuits such as digital PLLs, DLLs, ADCs, and on-chip jitter-monitoring circuits. Especially, high-resolution TDCs are increasingly employed in on-chip timing tests, such as jitter and clock skew measurements, as advanced fabrication technologies allow fine on-chip time resolutions. Its main purpose is to quantize the time interval of a pulse signal or the time interval between the rising edges of two clock signals. Similarly to ADCs, the performance of TDCs are also primarily characterized by Resolution, Sampling Rate, FOM, SNDR, Dynamic Range and DNL/INL. This work proposes and demonstrates 2nd order noise shaping Asynchronous SAR ADC based TDC architecture with highest resolution of 0.25 ps among current state of art designs with respect to post-layout simulation results. This circuit is a combination of low power/High Resolution 2nd Order Noise Shaped Asynchronous SAR ADC backend with simple Time to Amplitude converter (TAC) front-end and is implemented in 40nm CMOS technology. Additionally, special emphasis is given on the discussion on various current state of art TDC architectures.Electrical and Computer Engineerin

Design and testing of a radiation hardened 13-bit 80 MS/s pipeline ADC implemented in a 90nm standard CMOS process

Second International Workshop on Analog and Mixed Signal Integrated Circuits for Space Applications (AMICSA 2008), Sintra, Portugal, Setembro de 200

Low-Power Slew-Rate Boosting Based 12-Bit Pipeline ADC Utilizing Forecasting Technique in the Sub-ADCS

The dissertation presents architecture and circuit solutions to improve the power efficiency of high-speed 12-bit pipelined ADCs in advanced CMOS technologies. First, the 4.5bit algorithmic pipelined front-end stage is proposed. It is shown that the algorithmic pipelined ADC requires a simpler sub-ADC and shows lower sensitivity to the Multiplying DAC (MDAC) errors and smaller area and power dissipation in comparison to the conventional multi-bit per stage pipelined ADC. Also, it is shown that the algorithmic pipelined architecture is more tolerant to capacitive mismatch for the same input-referred thermal noise than the conventional multi-bit per stage architecture. To take full advantage of these properties, a modified residue curve for the pipelined ADC is proposed. This concept introduces better linearity compared with the conventional residue curve of the pipelined ADC; this approach is particularly attractive for the digitization of signals with large peak to average ratio such as OFDM coded signals. Moreover, the minimum total required transconductance for the different architectures of the 12-bit pipelined ADC are computed. This helps the pipelined ADC designers to find the most power-efficient architecture between different topologies based on the same input-referred thermal noise. By employing this calculation, the most power efficient architecture for realizing the 12-bit pipelined ADC is selected. Then, a technique for slew-rate (SR) boosting in switched-capacitor circuits is proposed in the order to be utilized in the proposed 12-bit pipelined ADC. This technique makes use of a class-B auxiliary amplifier that generates a compensating current only when high slew-rate is demanded by large input signal. The proposed architecture employs simple circuitry to detect the need of injecting current at the output load by implementing a Pre-Amp followed by a class-B amplifier, embedded with a pre-defined hysteresis, in parallel with the main amplifier to boost its slew phase. The proposed solution requires small static power since it does not need high dc-current at the output stage of the main amplifier. The proposed technique is suitable for high-speed low-power multi-bit/stage pipelined ADC applications. Both transistor-level simulations and experimental results in TSMC 40nm technology reduces the slew-time for more than 45% and shorts the 1% settling time by 28% when used in a 4.5bit/stage pipelined ADC; power consumption increases by 20%. In addition, the technique of inactivating and disconnecting of the sub-ADC’s comparators by forecasting the sign of the sampled input voltage is proposed in the order to reduce the dynamic power consumption of the sub-ADCs in the proposed 12-bit pipelined ADC. This technique reduces the total dynamic power consumption more than 46%. The implemented 12-bit pipelined ADC achieves an SNDR/SFDR of 65.9/82.3 dB at low input frequencies and a 64.1/75.5 dB near Nyquist frequency while running at 500 MS/s. The pipelined ADC prototype occupies an active area of 0.9 mm^2 and consumes 18.16 mW from a 1.1 V supply, resulting in a figure of merit (FOM) of 22.4 and a 27.7 fJ/conversion-step at low-frequency and Nyquist frequency, respectively

Design and Implementation of a Novel Flash ADC for Ultra Wide Band Applications

This dissertation presents a design and implementation of a novel flash ADC architecture for ultra wide band applications. The advancement in wireless technology takes us in to a world without wires. Most of the wireless communication systems use digital signal processing to transmit as well as receive the information. The real world signals are analog. Due to the processing complexity of the analog signal, it is converted to digital form so that processing becomes easier. The development in the digital signal processor field is rapid due to the advancement in the integrated circuit technology over the last decade. Therefore, analog-to -digital converter acts as an interface in between analog signal and digital signal processing systems. The continuous speed enhancement of the wireless communication systems brings out huge demands in speed and power specifications of high-speed low-resolution analog-to -digital converters. Even though wired technology is a primary mode of communication, the quality and efficiency of the wireless technology allows us to apply to biomedical applications, in home services and even to radar applications. These applications are highly relying on wireless technology to send and receive information at high speed with great accuracy. Ultra Wideband (UWB) technology is the best method to these applications. A UWB signal has a bandwidth of minimum 500MHz or a fractional bandwidth of 25 percentage of its centre frequency. The two different technology standards that are used in UWB are multiband orthogonal frequency division multiplexing ultra wideband technology (MB-OFDM) and carrier free direct sequence ultra wideband technology (DS-UWB). ADC is the core of any UWB receiver. Generally a high speed flash ADC is used in DS-UWB receiver. Two different flash ADC architectures are proposed in this thesis for DS-UWB applications. The first design is a high speed five bit flash ADC architecture with a sampling rate of 5 GS/s. The design is verified using CADENCE tool with CMOS 90 nm technology. The total power dissipation of the ADC is 8.381 mW from power supply of 1.2 V. The die area of the proposed flash ADC is 186 μm × 210 μm (0.039 mm2). The proposed flash ADC is analysed and compared with other papers in the literature having same resolution and it is concluded that it has the highest speed of operation with medium power dissipation. iii The second design is a reconfigurable five bit flash ADC architecture with a sampling rate of 1.25 GS/s. The design is verified using CADENCE tool with UMC 180 nm technology. The total power dissipation of the ADC is 11.71 mW from power supply of 1.8 V. The die area of the implementation is 432 μm × 720 μm (0.31104 mm2). The chip tape out of the proposed reconfigurable flash ADC is made for fabrication

Low-Power Slew-Rate Boosting Based 12-Bit Pipeline ADC Utilizing Forecasting Technique in the Sub-ADCS

The dissertation presents architecture and circuit solutions to improve the power efficiency of high-speed 12-bit pipelined ADCs in advanced CMOS technologies. First, the 4.5bit algorithmic pipelined front-end stage is proposed. It is shown that the algorithmic pipelined ADC requires a simpler sub-ADC and shows lower sensitivity to the Multiplying DAC (MDAC) errors and smaller area and power dissipation in comparison to the conventional multi-bit per stage pipelined ADC. Also, it is shown that the algorithmic pipelined architecture is more tolerant to capacitive mismatch for the same input-referred thermal noise than the conventional multi-bit per stage architecture. To take full advantage of these properties, a modified residue curve for the pipelined ADC is proposed. This concept introduces better linearity compared with the conventional residue curve of the pipelined ADC; this approach is particularly attractive for the digitization of signals with large peak to average ratio such as OFDM coded signals. Moreover, the minimum total required transconductance for the different architectures of the 12-bit pipelined ADC are computed. This helps the pipelined ADC designers to find the most power-efficient architecture between different topologies based on the same input-referred thermal noise. By employing this calculation, the most power efficient architecture for realizing the 12-bit pipelined ADC is selected. Then, a technique for slew-rate (SR) boosting in switched-capacitor circuits is proposed in the order to be utilized in the proposed 12-bit pipelined ADC. This technique makes use of a class-B auxiliary amplifier that generates a compensating current only when high slew-rate is demanded by large input signal. The proposed architecture employs simple circuitry to detect the need of injecting current at the output load by implementing a Pre-Amp followed by a class-B amplifier, embedded with a pre-defined hysteresis, in parallel with the main amplifier to boost its slew phase. The proposed solution requires small static power since it does not need high dc-current at the output stage of the main amplifier. The proposed technique is suitable for high-speed low-power multi-bit/stage pipelined ADC applications. Both transistor-level simulations and experimental results in TSMC 40nm technology reduces the slew-time for more than 45% and shorts the 1% settling time by 28% when used in a 4.5bit/stage pipelined ADC; power consumption increases by 20%. In addition, the technique of inactivating and disconnecting of the sub-ADC’s comparators by forecasting the sign of the sampled input voltage is proposed in the order to reduce the dynamic power consumption of the sub-ADCs in the proposed 12-bit pipelined ADC. This technique reduces the total dynamic power consumption more than 46%. The implemented 12-bit pipelined ADC achieves an SNDR/SFDR of 65.9/82.3 dB at low input frequencies and a 64.1/75.5 dB near Nyquist frequency while running at 500 MS/s. The pipelined ADC prototype occupies an active area of 0.9 mm^2 and consumes 18.16 mW from a 1.1 V supply, resulting in a figure of merit (FOM) of 22.4 and a 27.7 fJ/conversion-step at low-frequency and Nyquist frequency, respectively

Modeling and Implementation of A 6-Bit, 50MHz Pipelined ADC in CMOS

The pipelined ADC is a popular Nyquist-rate data converter due to its attractive feature of maintaining high accuracy at high conversion rate with low complexity and power consumption. The rapid growth of its application such as mobile system, digital video and high speed data acquisition is driving the pipelined ADC design towards higher speed, higher precision with lower supply voltage and power consumption. This thesis project aims at modeling and implementation of a pipelined ADC with high speed and low power consumption

A digital background calibration technique for pipeline ADCs

http://www.worldcat.org/oclc/4258158